KR20210002807U - expanding and flare processing complex device - Google Patents

Abstract

The present invention moves the expanding member that expands the inner diameter of the copper pipe in the horizontal and vertical directions to expand the diameter of the copper pipe by the expansion member without moving the heat exchanger, and at the same time expands the end of the pipe in the shape of a flare. It is about the device that does it.
The pipe expansion and flaring processing composite device according to the present invention expands the inner diameter of the copper pipe with the first expansion member in a state where one end of the copper pipe is held by the copper pipe fixing part of the first pipe expansion means, and then the second of the second expansion means The second supporting plate is lowered by the conveying part to expand the diameter of one end of some copper pipe with the lower expansion member, and at the same time, the end is expanded in the shape of a trumpet, and then the second fixing plate is lowered by the second conveying unit to the upper expansion member It is characterized by expanding the diameter of one end of the remaining copper tube and expanding the end of the tube in the shape of a trumpet. According to the present invention as described above, the combined pipe expansion and flaring processing apparatus has the advantage of being able to perform higher precision work because the pipe expansion member performing pipe expansion moves in the horizontal and vertical directions while the heat exchanger is fixed.

Description

Expanding and flare processing complex device

The present invention relates to a combined pipe expansion and flare processing device, and more specifically, by moving the expansion member for expanding the inner diameter of the copper pipe in the horizontal and vertical directions, the diameter of the copper pipe is expanded by the expansion member without moving the heat exchanger It relates to a device for performing flare processing, which simultaneously expands the tip into a trumpet shape.

In general, a copper pipe is a pipe that circulates a refrigerant, and has excellent thermal and electrical conductivity and is mainly used for refrigerant transport pipes such as refrigerators and air conditioners.

These copper tubes go through a tube expansion operation to expand the inner diameter when connecting the copper tubes to each other.

To this end, the tube expander for performing the tube expansion operation is configured such that the tube expansion tool is manually fixed and installed so that one end of the copper tube can be expanded at a time.

In this related prior art, Korean Patent No. 10-1215561, Korean Patent No. 10-1970329, etc. are disclosed.

The aforementioned Korean Patent Registration No. 10-1215561 is a vertical expansion device, which expands the inner diameter of the copper pipe by moving the expansion ball for expansion in the vertical direction to the vertically installed copper pipe.

However, in this case, since the copper tube is installed vertically, even a very small vibration causes a large shake at the upper end of the copper tube, and accordingly, there is a problem in that it is difficult to accurately insert the expansion ball into the copper tube.

In order to solve this problem, the operator must visually check the insertion state of the expansion ball, but since the upper end of the copper tube is installed high, it is difficult to directly check it, and there is a problem that there is a big risk of a safety accident when moving to a high position and checking it.

Korean Patent Registration No. 10-1970329 disclosed in order to solve this problem is a horizontal pipe expansion device, which expands the copper pipe by moving the heat exchanger in the horizontal direction.

However, in this case, since the pipe expansion operation is performed by moving the heat exchanger, a separate means for adjusting the position at which the heat exchanger is fixed is required to perform high-precision pipe expansion.

And, in the case of the prior art, the rod for inserting the first expansion tool for performing the first expansion is fixed to the fixing part of the rod for inserting the first expansion member by fastening bolts, and when replacing the rod for inserting the first expansion tool, first After separating the expansion ball from the long straight part of the rod for inserting the expansion tool, the straight part fixed to the rod fixing part should be separated.

Accordingly, it takes time to replace the rod for inserting the first expansion tool for maintenance or to replace it with parts of different sizes, and to replace the rod for inserting the first expansion tool with a straight part and an expansion ball There is a problem in that the efficiency of the work decreases due to the inconvenient work that can be done.

Korean Patent Registration No. 10-1215561 Korean Patent Registration No. 10-1970329

Accordingly, the object of the present invention is to solve the problems of the prior art as described above, by moving the expanding member for expanding the inner diameter of the copper pipe in the horizontal and vertical directions to increase the diameter of the copper pipe by the expansion member without moving the heat exchanger. It relates to an apparatus for performing flare processing of expanding and simultaneously expanding the tip into a trumpet shape.

According to the features of the present invention for achieving the object as described above, the pipe expansion and flaring processing complex apparatus according to the present invention includes: a heat exchanger fixing unit for fixing and supporting the heat exchanger; A first conveying part provided with a first expanding member for expanding the inner diameter of the copper pipe, an expanding member fixing part for fixing the first expanding member, and moving the first expanding member in a horizontal direction, and a copper pipe holding one end of the copper pipe a first pipe expansion means provided with a copper pipe fixing part to which a plurality of fixing members are mounted; A lower expansion member and an upper expansion member for expanding one end of the copper tube, a second fixing plate on which the lower expansion member and the upper expansion member are mounted, a second support plate mounted on one surface of the second fixing plate, and the second fixing plate or has a configuration including a second expansion means provided with a second transfer unit for moving the second support plate in the vertical and horizontal directions; The pipe expansion member fixing part is connected to a plurality of insertion plates through which a plurality of insertion holes into which the first expansion member is inserted are formed, a plurality of elevation plates provided to enable elevation between the partial insertion plates, and the elevation plates, respectively It is characterized in that it has a configuration that includes a cylinder that allows the lifting plate to be lifted.

The insert plate is composed of a first insert plate, a second insert plate, a third insert plate, and a fourth insert plate, the lower side of the insert hole formed in the first insert plate a first expansion member inserted into the insert hole A fixing groove provided with a fixing member for fixing is recessed, a fixing protrusion protruding upward is formed on the upper surface of the fixing member, and an elastic member for pressing the fixing member upward is provided inside the fixing member characterized by being

The first expansion member has a key groove recessed at one end thereof, and when inserted into the insertion hole of the first insertion plate, the fixing protrusion and the key groove of the fixing member are coupled to the first expansion member to the first insertion plate. It is characterized in that it is fixed.

The second transfer unit includes: a second guide member for fixing and supporting the second support plate and guiding a transfer direction of the second support plate; a first lifting cylinder mounted on the second guide member and configured to vertically elevate the second support plate; a second horizontal cylinder for moving the second support plate in a horizontal direction; It is mounted on the second support plate, characterized in that it has a configuration including a second lifting cylinder to allow the second fixing plate to be lifted up and down in the vertical direction.

The heat exchanger fixing part includes a fixing guide part for holding and fixing one end of the copper tube, and the fixing guide part includes: a holding member for fixing the copper tube by holding one end of the copper tube; a holding member fixing plate to which the holding member is fixedly mounted; and a pressure cylinder installed on one side of the holding member fixing plate and moving the holding member in a horizontal direction.

The pipe expansion and fretting process composite device according to the present invention has the following effects.

First, the pipe expansion and flaring processing composite device of the present invention expands the inner diameter of the copper pipe in a state in which the heat exchanger is horizontally arranged. Therefore, it is possible to minimize vibration and vibration compared to the vertical tube expansion device in which large vibrations occur even with very small vibrations, and it is possible to reduce safety accidents.

Second, the pipe expansion and flaring processing composite apparatus of the present invention is provided with a plurality of heat exchanger fixing plates for fixing the upper surface of the heat exchanger to the heat exchanger fixing part for fixing the heat exchanger, and a plurality of holding members for holding one side of the heat exchanger. Therefore, there is an advantage that the expansion of the copper pipe can be performed with higher precision by firmly fixing the heat exchanger to be expanded.

Third, a first conveying unit for moving the first expanding member for expanding the copper tube of the heat exchanger in a horizontal direction and a second conveying unit for moving the lower expanding member and the upper expanding member in horizontal and vertical directions are provided. When the copper pipe expansion of the heat exchanger is performed, the first pipe expansion is performed by the first conveying unit, and after the first expansion, when the first expanding member moves backward by the first conveying unit, the second pipe expansion means moves up and down in the vertical direction to raise and lower the copper pipe Expand one end of Accordingly, the copper tube expansion operation can be performed without moving the heat exchanger, and since the tube expansion operation is performed by moving only the tube expansion means while the heat exchanger is fixed, there is an advantage that the tube expansion operation is performed with higher precision.

Fourth, a plurality of lower expansion members and upper expansion members for expanding the diameter of one end of the copper pipe and expanding the end in a trumpet shape are installed in the second expansion means, respectively, at the lower end and upper end of one surface of the second fixing plate, respectively do. In this way, the second pipe expansion means equipped with the lower expansion member and the upper expansion member is lowered by the first lifting cylinder and then advanced by the second horizontal cylinder to expand the diameter of some copper pipes with the lower expansion member and at the same time, the end of the pipe is in the shape of a trumpet. , and lowering the second expanding means, which has moved backward by the second horizontal cylinder, to the second elevating cylinder, and then moving forward by the second horizontal cylinder to expand the diameter of one end of the remaining copper pipe with the upper expansion member and at the same time The tip is expanded in the shape of a trumpet. Therefore, there is an advantage that the load of the second horizontal cylinder for moving the second expansion means to expand the inner diameter of the copper tube is reduced.

Fifth, the first pipe expansion means is provided with a plurality of transport guide members to guide the transport of the first pipe expansion member deeply inserted into the copper tube. The first expanded pipe member is formed to be longer than the length of the copper pipe and is moved by the first conveying unit. At this time, the first expanded pipe member is moved while being supported by the conveying guide member so as not to be bent. Accordingly, there is an effect that the elongated first expanded tube member is easily inserted into the copper tube without being bent.

Sixth, a plurality of copper tube fixing members for holding one end of the copper tube while guiding the insertion direction of the first expanding tube member are mounted on the first tube expansion means. The copper tube fixing member holds and fixes one end of the copper tube during the first expanding operation, and the first expanding member penetrates the copper tube fixing member to expand the inner diameter of the copper tube. Accordingly, it is possible to prevent contraction of the length of the copper tube due to the insertion of the first expanding member during the first expansion of the copper tube.

Seventh, the first transfer unit to which the first expansion member is mounted is provided with a plurality of insertion plates and elevating plates. Here, the lifting plate is provided to enable lifting between some of the insertion plates, and when it is desired to expand the inner diameter of the copper tube by stacking heat exchangers of the same length or different lengths, the first expanding member is formed by elevating the lifting plate. It can be fixed to the insert plate by adjusting the length to the extent that it should be inserted into each copper tube. Accordingly, by adjusting the insertion length of the first expansion member to be inserted into each copper tube by raising and lowering the lifting plate according to the length of the copper tube to be expanded, the tube expansion operation can be easily performed.

Eighth, a key groove is recessed in one end of the first expanding pipe member, the lower expanding member, and the upper expanding member, thereby being fixed to the insertion hole of the insertion plate and the insertion hole of the second fixing plate, respectively. At this time, a fixing member is provided in the insertion hole of the insertion plate and the second fixing plate to be coupled to the key grooves of the first expansion member, the lower expansion member, and the upper expansion member. Conventionally, in order to fix the first expansion member, a screw for fixing is formed at one end thereof, and when replacing parts, the expansion ball and the long straight part must be separated separately, but the first expansion member of the present invention is a key formed at one end When the groove is inserted into the insertion hole of the insertion plate, the fixing member is caught in the key groove to achieve a solid fixation, and when replacing parts or changing to a part of a different size, the first expansion member is rotated without separately separating the expansion ball. It is only necessary to separate the coupling between the key groove and the fixing member. Therefore, a quick replacement operation is made compared to the prior art. By applying this advantage to the second pipe expansion means, there is an advantage in that the efficiency of work is also increased when replacing parts and changing to parts of different sizes.

1 is an overall perspective view showing a view from the right side of the tube expansion and flaring processing complex device according to an embodiment of the present invention.
Figure 2 is an overall perspective view showing the appearance from the left of the expansion and frea processing composite device according to an embodiment of the present invention.
3 is an enlarged view showing a holding member constituting an embodiment of the present invention.
Figure 4 is a perspective view showing the expansion member fixing portion of the transfer unit constituting the embodiment of the present invention.
5 is a side view showing a state in which the first expansion pipe member is inserted and fixed to the pipe expansion member fixing part constituting the embodiment of the present invention when three heat exchangers having different lengths are expanded.
6 is an enlarged view showing a state in which the fixing member is mounted in the insertion hole of the insertion plate constituting the embodiment of the present invention.
7 is a side view showing a process in which the first expanding pipe member constituting the embodiment of the present invention is inserted into the insertion hole of the insertion plate and fixed by the fixing member.
8 is a partially enlarged view showing a copper tube fixing part and a second expanding means constituting an embodiment of the present invention.
9 is a perspective view showing a state in which the first expansion pipe member penetrates the copper pipe fixing member of the copper pipe fixing member constituting the embodiment of the present invention.
10 is an enlarged view showing the shape of the upper pipe expansion member of the second pipe expansion means constituting the embodiment of the present invention.
11 is an overall perspective view showing a state in which the first expansion member constituting the embodiment of the present invention is moved in the horizontal direction;
12 is an overall perspective view showing a state in which the second support plate constituting the embodiment of the present invention is moved in the vertical direction;

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the complex apparatus for expansion and fretting according to the present invention will be described in detail.

1 is an overall perspective view showing a view from the right side of the expansion and flaring processing complex device of the present invention, Figure 2 is an overall perspective view showing the view from the left side of the expansion and flaring processing composite device of the present invention. 3 is an enlarged view showing the holding member, FIG. 4 is a perspective view showing the expansion tube member fixing part of the conveying part constituting an embodiment of the present invention, and FIG. 5 is an enlarged view of three heat exchangers having different lengths. It is a side view showing a state in which the first expansion member is inserted and fixed to the fixing part of the expansion member constituting an embodiment of the present invention. 6 is an enlarged view showing a state in which the fixing member is mounted on the insertion hole of the insertion plate constituting the embodiment of the present invention, and FIG. 7 is the first expansion tube member is inserted into the insertion hole of the insertion plate and fixed by the fixing member This is a side view showing the process. 8 is a partially enlarged view showing the copper tube fixing part and the second expanding means constituting the embodiment of the present invention, and FIG. 10 is an enlarged view showing the shape of the upper expansion member of the second pipe expansion means, FIG. 11 is an overall perspective view showing a state in which the first expansion member is moved in the horizontal direction, and FIG. 12 is the second support plate moved in the vertical direction It is an overall perspective view showing the finished state.

As shown in these drawings, the pipe expansion and flaring processing composite device according to an embodiment of the present invention expands the inner diameter of the copper pipe constituting the fin-tube heat exchanger and at the same time expands the end of the copper pipe through flare processing It is a device for expanding wealth in the shape of a trumpet.

In general, a finned tube heat exchanger transfers heat between fluids such as air, and is mainly used in cooling systems such as air conditioners and refrigerators.

Such a fin tube type heat exchanger includes a plurality of stacked fin plates 80 and a copper tube 82 installed through the stacked fin plates 80 .

Here, the copper tube 82 is a passage for transferring the fluid, is formed in a U-shape and is installed through the stacked pin plates 80 at regular intervals, and both ends of the copper tube 82 (U-shape) The upper end or lower end of the shape) is installed to protrude partly to the outside of the heat exchanger 8 .

When the copper tube 82 is to be connected to each other, the copper tube 82 is expanded by a device that expands the inner diameter of the copper tube 82 .

The pipe expansion and flaring processing composite device according to the present invention is a heat exchanger for fixing and supporting the heat exchanger transfer unit 1 for transferring the heat exchanger 8 and the heat exchanger 8 transferred from the heat exchanger transfer unit 1 . A fixing part (2), a first pipe expansion means (3) for expanding the inner diameter of the copper pipe (82) of the heat exchanger (8) fixed and supported by the heat exchanger fixing part (2), and the first expansion means ( It is characterized in that it comprises a second pipe expansion means (4) for expanding one end of the copper pipe (82) after expansion by 3).

In particular, the combined tube expansion and flaring processing apparatus of the present invention having such a configuration can perform a high-precision tube expansion operation without transferring the heat exchanger 8 when the copper tube 82 is expanded, and the first tube expansion means (3) And the second pipe expansion means (4) by moving the expansion members mounted on each in the horizontal and vertical directions to rapidly expand the expansion.

This will be described in more detail for each configuration as follows.

First, the heat exchanger transfer unit 1 is a device for transferring the heat exchanger 8 to a heat exchanger fixing unit 2 to be described later.

Such a heat exchanger transfer unit 1 includes a rectangular frame-shaped frame, a transfer member 12 for transferring the heat exchanger 8 , and a support member 10 for supporting the heat exchanger 8 . do.

Here, the rectangular frame-shaped frame is a frame for fixing and supporting the conveying member 12 and the supporting member 10, and the conveying member 12 and the supporting member 10 are fixed to and supported by a plurality of the conveying member 12 and the supporting member 10 in the upper frame of the frame. made to be supported.

The transfer member 12 is for transferring the heat exchanger 8 to the heat exchanger fixing part 2, and is composed of a motor, a rotating belt, etc., and transfers the heat exchanger 8 in both directions. made to be able to

Since the transfer member 12 having such a configuration has the same configuration and operation as that of a general conveyor belt, a detailed description thereof will be omitted.

The support member 10 supports the heat exchanger 8, and for more stable support, it is preferably formed of a plate having a shape such as a rectangular parallelepiped, and is fixed to the upper frame of the rectangular frame by screws or the like.

A plurality of the transfer member 12 and the support member 10 are provided in the upper frame of the frame, and a plurality of transfer members 12 are provided spaced apart from each other by a predetermined interval, and between the transfer members 12, the plurality of transfer members 12 are provided. Support members 10 are provided one by one.

Accordingly, the heat exchanger 8 is supported by the support member 10 and the heat exchanger 8 can be transferred to the heat exchanger fixing part 2 to be described later by the rotation of the transfer member 12 . have.

Next, the heat exchanger fixing unit 2 is a device for fixing and supporting the heat exchanger 8 transferred from the heat exchanger conveying unit 1 .

The heat exchanger fixing part 2 is largely configured to include a heat exchanger support member 20 , a heat exchanger transfer member 28 , a heat exchanger fixing plate 22 , a fixing plate support 24 , and a fixing guide part 26 . .

Here, the heat exchanger support member 20 supports the heat exchanger 8 transferred from the heat exchanger transfer unit 1 .

The heat exchanger support member 20 plays the same role as the support member 10 of the heat exchanger transfer unit 1 and is formed in a rectangular parallelepiped shape to support the heat exchanger 8 .

And, the heat exchanger transfer member 28 performs the same configuration and the same role as the transfer member 12 of the heat exchanger transfer unit 1 .

The heat exchanger support member 20 and the heat exchanger transfer member 28 are configured in the same manner as in the heat exchanger transfer unit 1 .

In other words, the heat exchanger support members 20 are positioned one by one between the heat exchanger transfer members 28 mounted to be spaced apart from each other by a predetermined distance to perform their respective functions.

Accordingly, it is possible to easily move the heat exchanger 8 from the heat exchanger transfer unit 1 to the heat exchanger fixing unit 2, and vice versa, from the heat exchanger fixing unit 2 to the heat exchanger transfer unit 1 as well. The heat exchanger 8 can be moved easily.

The heat exchanger fixing plate 22 is such that the heat exchanger 8 transferred from the heat exchanger transfer unit 1 is fixed without flow.

The heat exchanger fixing plate 22 is configured to be lifted up and down by a fixing plate support 24 to be described later, and is positioned above the heat exchanger 8 while the heat exchanger 8 is being transferred from the heat exchanger transfer unit 1, and the heat exchanger 8 ) is moved to the upper side of the heat exchanger support member 20 and then descends so that the heat exchanger 8 is positioned without flow.

The fixing plate support 24 is a type of cylinder, and is formed in a rod shape and mounted on the upper surface of the heat exchanger fixing plate 22 .

Accordingly, when the heat exchanger 8 is not allowed to flow on the upper surface of the heat exchanger support member 20, the fixed plate support 24 flows in the vertical direction by the operation of the cylinder. The heat exchanger fixing plate 22 may flow in the vertical direction at the same time to prevent the heat exchanger 8 from deviated from a predetermined position or to release the fixation.

A plurality of the heat exchanger fixing plate 22 and the fixing plate support 24 are provided, and it is preferable that they are mounted in a state spaced apart from each other by a predetermined distance.

A fixing guide part 26 is provided on the right side (refer to FIG. 1 ) of the heat exchanger fixing plate 22 located on the rightmost among the plurality of heat exchanger fixing plates 22 provided as described above.

The fixed guide part 26 is to hold one end of the heat exchanger 8 transferred from the heat exchanger transfer unit 1 so as not to be separated from the position for performing the pipe expansion during the pipe expansion operation.

In more detail, as described above, a plurality of U-shaped copper tubes 82 are installed through the heat exchanger 8 . The copper tube 82 installed through the heat exchanger 8 has a shape in which only the U-shaped upper part is visible on one side of the heat exchanger 8 and only the U-shaped lower part is visible on the other side. .

Here, the fixing guide part 26 firmly fixes the heat exchanger 8 by holding one end of the copper tube 82 where the U-shaped lower part is visible.

The fixing guide part 26 is configured to include a holding member 260 , a holding member fixing plate 262 , a pressure cylinder 264 , and a fixing plate transfer means 266 .

The holding member 260 holds one end of the copper tube 82 so that the heat exchanger 8 does not move. The holding member 260 of the present invention has a U-shaped lower portion of the copper tube 82 By holding the , the heat exchanger 8 does not flow and the length of the copper tube 82 is prevented from being contracted when the inner diameter of the copper tube 82 is expanded.

At this time, it is preferable that the holding member 260 has the same shape as the outer circumferential surface of one end of the copper tube 82 to be held.

That is, the holding member 260 of the U-shaped copper tube 82 has to hold one end of the copper tube 82 that is formed to be the same as the U-shaped lower part to make a firm fixation, so the holding member 260 is also the same It is preferable to form a shape.

This holding member 260 is one of the types of general chucks, and is mounted and fixed to the plate-shaped holding member fixing plate 262 .

Since a plurality of the copper tubes 82 are provided in the heat exchanger 8, the number of holding members 260 is preferably fixed to the holding member fixing plate 262 by the same number as the number of the copper tubes 82.

In addition, as shown in FIG. 3 , when the heat exchangers 8 of different lengths are stacked in the holding member fixing plate 262, the holding member 260 holds each heat exchanger 8 according to the length. A plurality of the holding members 260 are mounted on each floor because it is formed in a step form so as to be firmly fixed.

A pressure cylinder 264 is further provided on one side of the holding member fixing plate 262 .

The pressure cylinder 264 is a cylinder that pushes or pulls the holding member fixing plate 262 in the horizontal direction, and when the heat exchanger 8 is transferred to the heat exchanger fixing part 2, the copper tube 82 Before performing pipe expansion, the heat exchanger 8 should be fixed without flow. At this time, the pressure cylinder 264 presses the holding member fixing plate 262 toward the heat exchanger 8 toward the holding member 260, so that the copper pipe ( 82) to fix the heat exchanger (8) by holding one end of it.

In addition, after the copper pipe 82 expansion operation is finished, the holding member fixing plate 262 is returned to its original position by the pressure cylinder 264 and the holding member 260 is separated from the copper pipe 82 to separate the heat exchanger (8). will release the fixation of

Since such a pressure cylinder 264 is a type of a general cylinder, a detailed description thereof will be omitted.

The components of the heat exchanger fixing part 2 described above are each operated by the fixing plate transfer means 266 .

Next, the first pipe expansion means 3 is installed on one side of the heat exchanger fixing part 2 and is a means for expanding the inner diameter of the copper pipe 82 .

The first pipe expansion means 3 is largely composed of a first pipe expansion member 37, a first transport part 36, a transport guide member 32, a transport guide rail 34, and a copper pipe fixing part 30, etc. is comprised of

These components are provided on the upper surface of the frame formed in the shape of a square frame, and the first expanding member 37 and the copper pipe fixing part 30 are moved in the horizontal direction to expand the inner diameter of the copper pipe 82 and at the same time to expand the pipe. The end of the copper tube 82 is fixed so as not to decrease in length.

The above configurations will be described in detail as follows.

First, the first expansion member 37 is a member for expanding the inner diameter of the copper pipe 82 , and includes a straight line portion 370 elongated in the horizontal direction, and a first installed on one side of the straight line portion 370 . It is made, including the expansion tool (372).

The first expansion member 37 formed in this way is moved in the horizontal direction by a first transfer part 36 to be described later, and the first expansion tool 372 is first inserted into one end of the copper pipe 82 and the Next, the long straight portion 370 is inserted deep inside the copper tube 82 , so that the inner diameter of the copper tube 82 can be enlarged by the first expanding tube member 37 .

Here, the copper pipe 82 expanded by the first pipe expansion member 37 has the same thickness as the stacked thickness of the fin plate 80 of the heat exchanger 8 .

On the other hand, as shown in FIG. 7 , a key groove 374 is formed in a partial section depression at one end of the straight part 370 constituting the first expanding pipe member 37 .

The key groove 374 is a groove formed for solid fixing to the first transfer part 36 to be described later, and as seen in the accompanying drawings, the same surface as the outer peripheral surface of the straight part 370 toward the right side (based on FIG. 5 ). It is formed in an inclined shape having

The first expanding pipe member 37 having such a key groove 374 is fixedly mounted to the first transfer unit 36 by the key groove 374 and moves forward or backward according to the movement of the first transfer unit 36 . .

As described above, the first conveying part 36 moves the first expanding pipe member 37 in the horizontal direction by moving forward or backward at the same time as fixing the first expanding pipe member 37 .

The first transfer unit 36 is provided with a plurality of parts for fixing the first expanding pipe member 37 to the hexahedral first support plate 360a'.

As shown in the accompanying drawings, two or more supporting members 360f are mounted on the first supporting plate 360a' in a vertical direction.

The support member 360 is formed in a hexahedral plate shape, and at an upper end of the first expanded pipe member 37, one end of the first expanded pipe member 37 is inserted through a hole for supporting it ( holes) are formed.

In addition, the expansion member fixing part 360 is mounted on one surface of the support member 360f.

The pipe expansion member fixing part 360 has a configuration including a plurality of insertion plates 360b, 360c, 360d, and 360e, lifting plates 350, 352, 354, 356, and cylinders 361 and 361'.

The insertion plates 360b, 360c, 360d, 360e360b, 360c, 360d, and 360e are formed in a plate shape, and a plurality of insertion holes 362 for inserting the first expanding pipe member 37 are formed therethrough.

The inserting plates 360b, 360c, 360d, and 360e include a first inserting plate 360b, a second inserting plate 3660c, a third inserting plate 360d, and a fourth inserting plate 360e.

The reason why the plurality of insert plates 360b, 360c, 360d, and 360e are provided is that each copper tube is stacked with heat exchangers 8 having the same length or different lengths to expand the inner diameter of the copper tube 82. This is to adjust the degree to which the first expanding tube member 37 is inserted into the copper tube 82 according to the length of (82).

The first inserting plate 360b is a plate into which one end of the first expanding pipe member 37 is inserted and fixed.

In this case, a fixing groove 363 is recessed for a predetermined section in a portion of the bottom surface of the insertion hole 362 formed in the first insertion plate 360b.

As shown in the accompanying drawings, the fixing groove 363 is formed with a lower surface protruding for a certain section in the left-right direction (based on FIG. 4). A fixing member 364 for fixing the first expanded pipe member 37 to be inserted through is provided.

The fixing member 364 has a shape such as a hexahedron when viewed from the front as shown in Figs. , a fixing protrusion 366 protruding upward for a certain section is formed on the upper surface.

And, the bottom surface of the fixing member 364 is formed to be depressed upwardly, so that the elastic member 365 such as a spring is accommodated therein.

The fixing member 364 having such a shape is accommodated in the fixing groove 363 .

At this time, the locking protrusions 367 of the fixing member 364 are positioned to be accommodated in the protruding portions of the fixing grooves 363 to the left and right (based on FIG. 4 ), so that only within the protruding portions of the fixing grooves 363 in the vertical direction. can be moved to

Accordingly, when the first expanding pipe member 37 is inserted into the insertion hole 362, the fixing member 364 is pressed from the upper side by the outer surface of the first expanding pipe member 37, and the fixing member ( The locking protrusion 367 of 364 descends to the bottom of the fixing groove 363 , so that the first expansion pipe member 37 can be easily inserted through the insertion hole 362 .

And, the key groove 374 of the first expansion member 37 and the fixing member 364 while rotating the first expansion member 37 to the left or right in the state inserted into the insertion hole 362 The fixing protrusion 366 is coupled to it.

When the key groove 374 and the fixing protrusion 366 are coupled, the fixing member 364 is raised upward by the elastic member 365 so that the first expansion pipe member 37 is fixed to the insertion hole 362 . do.

Here, since the locking protrusion 367 is caught in the protruding portion of the fixing groove 363 , the fixing member 364 is not separated from the fixing groove 363 .

The first expansion member 37 is fixed to the expansion member fixing part 360 by the fixing member 364 .

A method in which the first expanding pipe member 37 is mounted by the fixing member 364 will be described in detail with reference to the accompanying FIG. 7 as follows.

First, one end of the first expansion member 37 having the key groove 374 is inserted into the insertion hole 362 of the expansion member fixing part 360 .

At this time, it is preferable to insert the first expansion member 37 from the right to the left (based on FIG. 5).

Here, the fixing protrusion 366 of the fixing member 364 comes in contact with the outer circumferential surface of the first expanding pipe member 37, and thus descends toward the bottom of the fixing groove 363 by the elastic member 365 .

And, when the fixing protrusion 366 is positioned in the key groove 374 of the first expanding pipe member 37 while the first expanding pipe member 37 is inserted, the fixing protrusion 366 is fixed by the elasticity of the elastic member 365 . The member 364 rises and the first expansion pipe member 37 is firmly fixed with the fixing protrusion 366 .

As such, the first expansion member 37 mounted on the expansion member fixing unit 360 may be separated as follows.

First, the first expansion pipe member 37 is pushed to the rear (left side in FIG. 5).

At this time, the fixing protrusion 366 of the fixing member 364 is descended by the elastic member 365 along the inclined surface of the key groove 374 from the key groove 374 in the left figure of FIG. separated as easily as

Then, by rotating the first expansion member 37, the key groove 374 and the fixing protrusion 366 of the fixing member 364 are positioned so that they do not face each other.

Then, the first expansion member 37 is pushed forward (right side in FIG. 5) to separate it from the expansion member fixing part 360.

Accordingly, the first expansion member 37 can be firmly fixedly mounted to the expansion member fixing part 360, and when replacing the mounted parts, the first expansion member 37 can be installed without using a separate tool. ), it can be easily separated through rotation after pushing it back, so it has the advantage of quick replacement.

A second inserting plate 360c is provided on the rear surface of the first inserting plate 360b.

The second inserting plate 360c is formed of a plate having the same size and shape as the first inserting plate 360b.

In addition, holes having the same shape and number as the insertion holes 362 of the first inserting plate 360b are formed through the second inserting plate 360c, and these holes are formed through the first inserting plate 360b. It is formed at the same position as the insertion hole 362 formed in the insertion plate 360b.

Accordingly, one end of the first expanding pipe member 37 may be sequentially inserted through the first inserting plate 360b and the second inserting plate 360c, and fixed with the key groove 374 . A state fixed by the member 364 may be maintained.

The third inserting plate 360d is a plate positioned on the rear surface of the second inserting plate 360c.

The third inserting plate 360d also has a plate-like shape like the first inserting plate 360b and the second inserting plate 360c, and the insertion hole 362 of the first inserting plate 360b and A plurality of holes are formed through the same position and number.

In addition, the fourth inserting plate 360e is provided on the rear surface of the third inserting plate 360d.

The fourth inserting plate 360e is also made in the same shape as a plate, and has the same number of holes in the same shape, size, and position as the holes formed in the third inserting plate 360d. through is formed.

The first inserting plate 360b, the second inserting plate 360c, the third inserting plate 360d, and the fourth inserting plate 360e formed in this way are the centers of the holes formed in each as shown in the accompanying drawings. The insertion plates 360b, 360c, 360d, 360e360b, 360c, 360d, and 360e are positioned to form the same point with each other, and the second support plate 360a'' is mounted on the side surface of the support member 360f in the horizontal direction. ) is mounted in the vertical direction on the upper surface of the

Meanwhile, the lifting plates 350 , 352 , 354 and 356 are further provided between the partial insertion plates 360b , 360c , 360d and 360e .

The lifting plates 350 , 352 , 354 , 356 prevent the end of the first expansion member 37 sequentially inserted through the first inserting plate 360b and the second inserting plate 360c from being inserted any more. it's a plate

The lifting plates 350 , 352 , 354 , and 356 are installed to enable lifting by being connected to the cylinders 361 and 361 ′, respectively.

The lifting plates 350, 352, 354, 356 include upper lifting plates 350 and 356 located at the upper end of the inserting plates 360b, 360c, 360d, 360e360b, 360c, 360d, and 360e, and the inserting plate ( 360b, 360c, 360d, 360e360b, 360c, 360d, 360e) is composed of the lower elevating plate (352, 354) located at the lower end.

The upper lifting plates 350 and 356 include the first upper lifting plate 350, the fourth inserting plate 360e, and the supporting member provided between the second inserting plate 360c and the third inserting plate 360d. It is composed of a second upper lifting plate 356 provided between (360f).

In addition, the lower lifting plates 352 and 354 include the first lower lifting plate 352 and the third inserting plate 360d provided between the second inserting plate 360c and the third inserting plate 360d. It is composed of a second lower lifting plate 354 provided between the fourth inserting plate (360e).

A hole is not formed on the upper surface of the first upper lifting plate 350 and the second upper lifting plate 356 to prevent the first expanding pipe member 37 from being inserted, and the lower end of the 1 The insertion hole 362 is formed so that the expansion member 37 is inserted.

In addition, the first lower lifting plate 352 and the second lower lifting plate 354 have a hexahedral shape elongated in the horizontal or vertical direction as shown in FIG. 4 of the insertion plates 360b, 360c, 360d, and 360e.

Each of the upper elevating plates 350 and 356 and the lower elevating plates 352 and 354 having such a shape is installed to enable elevating as they are connected to the cylinders 361 and 361'.

Here, the cylinders 361 and 361' are positioned and connected to the upper side of the first upper lifting plate 350 to elevate the first upper lifting plate 350, the first upper cylinder 361a, and the second A second upper cylinder 361b positioned and connected to the upper side of the upper lifting plate 356 to elevate the second upper lifting plate 356, and provided on the upper surface of the first supporting plate 360a', the first lower portion The first lower cylinder 361'a, which is located and connected to the lower side of the lifting plate 352 to raise and lower the first lower lifting plate 352, and the first supporting plate 360a' are provided on the upper surface of the second It is located and connected to the lower side of the lower lifting plate 354 is configured to include a second lower cylinder (361'b) for elevating the second lower lifting plate (354).

By having such a configuration, the upper lifting plates 350 and 356 and the lower lifting plates 352 and 354 can be freely raised and lowered by the upper cylinders 350 and 356 and the lower cylinders 352 and 354 connected to each other. .

A heat exchanger (8) having the same length as the method in which the length of the first expansion member (37) is adjusted using the lifting plates (350, 352, 354, 356) in the fixing part of the expansion member (360) When stacking the heat exchangers 8 having different lengths and stacking the heat exchangers 8 will be described as an example as follows.

First, before expanding the inner diameter of each copper tube 82 to the first expanding member 37, when the heat exchanger 8 having the same length is stacked to perform pipe expansion, the first expansion member ( 37) should be fixed to the insertion plates 360b, 360c, 360d, and 360e.

Here, the first upper lifting plate 350 is lowered by the first upper cylinder 361a, and the first lower lifting plate 352 is raised by the first lower cylinder 361'a. One end of the first expansion pipe member 37 is inserted into the first inserting plate 360b and the second inserting plate 360c.

In this case, the first expansion member 37 may prevent further insertion by the first upper lifting plate 350 and the first lower lifting plate 352 .

And, when the pipe expansion operation is performed by stacking three heat exchangers 8 having different lengths, the length of the copper pipe 82 is different for each heat exchanger 8, so each The first expanded pipe member 37 is fixed to the insertion plates 360b, 360c, 360d, and 360e with a length that allows the first expanded pipe member 37 to be inserted into the copper pipe 8 of the .

For example, the length of the heat exchanger 8 located at the upper part is the shortest among the three stacked heat exchangers 8, then the heat exchanger 8 located in the middle part, and the heat exchanger 8 located in the lower part, in that order In the case of the heat exchanger 8 located at the upper part when the length is formed as , since it has a short copper tube 82, in order to expand the inner diameter of the copper tube 82, the first expanding tube member 37 is inserted inside the tube. is that the insertion portion of the copper tube 82 must be mounted on the insertion plates 360b, 360c, 360d, and 360e so that it has the same length or shorter than the length of the copper tube 82 .

In addition, in the case of the heat exchanger 8 located in the middle part and the lower part, the first expanding pipe member 37 inserted into each copper pipe 82 is similar to the above to match the length of the copper pipe 82 positioned in the middle part and the lower part. It is to be mounted on the insert plates 360b, 360c, 360d, and 360e.

In order to be inserted in this way, the first expanded tube member 37 for expanding the copper tube 82 positioned at the upper portion is preferably formed with a short insertion part inserted into the inner side of the copper tube 82, and for this purpose, the first expanded tube member 37 One end of the should be deeply inserted into the insertion plate (360b, 360c, 360d, 360e).

At this time, since the first upper lifting plate 350 is raised by the first upper cylinder 361a, the first expanding pipe member 37 located above the insertion plates 360b, 360c, 360d, and 360e is It can be inserted into the insertion hole 362 of the third insertion plate 360d by sequentially passing through the insertion hole 362 of the first insertion plate 360b and the second insertion plate 360c.

Here, an insertion hole 362 for guiding the insertion of the first expanding pipe member 37 is formed in the lower portion of the first upper lifting plate 350 to thereby provide the first insertion plate 360b and the second insertion plate 360c. ), the first expanding pipe member 37 passing through the upper part may be inserted into the third inserting plate 360d after passing through it.

Then, the first expansion member 37 penetrating the upper portion of the third inserting plate 360d is inserted through the insertion hole 362 formed in the upper part of the fourth inserting plate 360e, and at this time, the second upper part The lifting plate 356 is lowered by the second upper cylinder 361b so that the end of the first expanding pipe member 37 passing through the upper part of the fourth inserting plate 360e is placed on the second upper lifting plate 356. This can prevent further insertions.

On the other hand, when the insertion portion of the first expanding pipe member 37 inserted into the copper pipe 82 is to be made short, the first expanding pipe member 37 is a hole formed in the lower portion of the second upper lifting plate 356 . ) may be installed through the

Accordingly, by inserting the first expanding tube member 37 into the inserting plates 360b, 360c, 360d, and 360e according to the length of the copper tube 82 located on the upper portion, the inner diameter thereof can be expanded.

In this way, the first expanding tube member 37 for expanding the inner diameter of the copper tube 82 located in the middle portion is mounted on the middle portion of the insertion plates 360b, 360c, 360d, and 360e.

Since the length of the copper tube 82 located in the middle is longer than the length of the copper tube 82 located at the upper portion, the degree to which the first expanded tube member 37 is inserted into the insertion plates 360b, 360c, 360d, and 360e. It is preferable to mount the insertion plate (360b, 360c, 360d, 360e) shorter than the first expansion member 37 mounted on the upper part.

At this time, since the first upper lifting plate 350 is raised by the first upper cylinder 361a, the first expanding member 37 mounted in the middle of the inserting plates 360b, 360c, 360d, and 360e is the It can be easily inserted through the third inserting plate (360d).

Here, the second lower elevating plate 354 is raised by the second lower cylinder 361'b, so that the first expanding member 37 is mounted in the middle of the inserting plates 360b, 360c, 360d, and 360e. to prevent further insertion.

Next, the first expansion member 37 for expanding the copper tube 82 located at the lower portion is mounted on the lower portion of the insertion plates 360b, 360c, 360d, and 360e.

Since the length of the copper tube 82 located in the lower portion is longer than the length of the copper tube 82 located in the middle portion, the degree to which the first expanding tube member 37 is inserted into the insertion plates 360b, 360c, 360d, and 360e is determined. It is preferable to mount shorter than the first expanding pipe member 37 mounted on the middle portion of the insertion plate (360b, 360c, 360d, 360e).

At this time, as the first lower lifting plate 352 is raised by the first lower cylinder 361'a, the first expanding member 37 mounted on the lower portion of the inserting plates 360b, 360c, 360d, and 360e is No further insertion is made by the first lower lifting plate 352 .

In this way, the upper cylinder 361 and the lower cylinder 361' are operated according to the length of the copper tube 82 to be expanded in this way, and the upper and lower elevating plates 350 and 356 and the lower elevating plates 352 and 354 are operated. When performing the pipe expansion operation of the copper tube 82 having a step difference by elevating it, the tube expansion operation can be easily performed by adjusting the length of the insertion part of the first expansion tube member 37 to be inserted into each.

As such, a plurality of first expansion members 37 fixed and mounted to the expansion member fixing part 360 are mounted on the insert plates 360b, 360c, 360d, and 360e, and the first transport part 36 is moved. By moving forward or backward, the inner diameter of a plurality of copper tubes 82 is expanded at once.

A transfer guide rail 34 is provided on the upper surface of the frame of the first expanding means 37 to guide the moving direction of the first expanding member 37 .

The transfer guide rail 34 is a member for guiding the movement direction of the first transfer unit 36 so that the first expanded tube member 37 is inserted into the copper tube 82 .

These transport guide rails 34 are provided in pairs in the horizontal direction on the upper frame of the rectangular frame shape.

The plate-shaped first transfer part 36 may move horizontally along the transfer guide rail 34 by having both ends of the first transfer part 36 engage and mount on the transfer guide rail 34 , respectively.

Meanwhile, a transfer guide member 32 to be described later is further mounted on the transfer guide rail 34 .

The transfer guide member 32 is for supporting the first expanding pipe member 37 .

Since the first expanded pipe member 37 is formed to be longer than the length of the copper pipe 82, if it is moved only by the first conveying part 36, the first expanding pipe member 37 can be bent, so a plurality of conveying A guide member 32 is provided.

Accordingly, as the first transfer unit 36 moves in the horizontal direction and the plurality of transfer guide members 32 move in the same direction, it is possible to prevent bending of the first expanding pipe member 37 .

This transfer guide member 32 is located on the right side (refer to FIG. 2) of the first transfer unit 36, has a plate-like shape, and is supported while passing through a plurality of the first expanding tube member 37. It is preferable that a plurality of holes are formed so that the

Both ends of the transfer guide member 32 are mounted on the transfer guide rail 34 so that they can be moved in the same direction as the movement direction of the first expanded tube member 37, thereby moving in the horizontal direction.

At this time, the distance maintaining blocks 33 are respectively mounted at both ends of the transfer guide member 32 as shown in the drawing.

The distance maintaining block 33 is a block in the shape of a rectangular parallelepiped, and is provided at each end of the transfer guide member 32 provided in plurality to maintain the distance of each of the adjacent transfer guide members 32, as well as the This is to allow the transfer guide member 32 to move in the horizontal direction along the transfer guide rail 34 by being engaged with the transfer guide rail 34 .

In addition, although not shown in the drawing, the transfer guide members 32 adjacent to each other are connected by a chain, etc., thereby providing easy movement of the transfer guide member 32 when moving forward or backward in the horizontal direction and at the same time as the chain of the chain. Keep a certain distance as long as it is.

Accordingly, when the inner diameter of the copper tube 82 is expanded, the first expanded tube member 37 is supported by the first transfer unit 36 and the transfer guide member 32 to move in the horizontal direction.

On the other hand, the first pipe expansion means (3) is further provided with the copper pipe fixing part (30).

When the inner diameter of the copper tube 82 is expanded by the first expansion member 37, the copper tube fixing part 30 is located on one side of the copper tube 82 so that the length of the copper tube 82 is not contracted by the expansion operation. will grab the end.

The copper tube fixing part 30 is located in front of the transfer guide member 32 located on the rightmost side (refer to FIG. 2) among the plurality of transfer guide members 32 provided in the first pipe expansion means 3, 1 During the pipe expansion operation by the expansion member 37, one end of the copper pipe 82 is held and fixed.

The copper tube fixing member 30 has a plate-like shape, and a copper tube fixing member 310 that holds one end of the copper tube 82, and a first fixing plate on which a plurality of the copper tube fixing members 310 are mounted. (31) is included.

As shown in FIGS. 8 and 9 , the copper tube fixing member 310 includes an insertion tube 311 elongated in the horizontal direction and a fixing chuck 312 for holding one end of the copper tube 82 .

One end of the insertion tube 311 is fixedly mounted to a hole formed through the first fixing plate 31 , and the fixing chuck 312 is mounted on the other end thereof as shown in FIG. 9 .

Here, the fixing chuck 312 has a shape capable of holding one end of the copper tube 82 as shown in FIG. 9 .

Since the fixing chuck 312 is one of the types of collet chucks mainly used to hold parts, a detailed description thereof will be omitted.

On the other hand, the insertion tube 311 and the fixing chuck 312 fixed to the first fixing plate 31 are to be inserted into the copper tube 82 as the first expanding tube member 37 penetrates as shown in FIG. 9 . It is preferable that the inside is made in a hollow shape so as to be able to do so.

A first horizontal cylinder 314 for moving the first fixing plate 31 in a horizontal direction is further provided on the rear surface of the first fixing plate 31 .

Here, since the first horizontal cylinder 314 is the same as a general cylinder, a detailed description thereof will be omitted.

Since the first horizontal cylinder 314 is mounted on the rear surface of the first fixing plate 31 , the first fixing plate 31 can be moved horizontally, and the copper tube can be moved by the first fixing plate 31 . A fixing member 310 may hold one end of the copper tube 82 .

Accordingly, when the copper pipe 82 is expanded by the first pipe expansion means 3, the first fixing plate 31 is advanced by the first horizontal cylinder 314, so that the copper pipe fixing member 310 is After holding and fixing one end of the copper tube 82, the first expanding tube member 37 is moved by the advancement of the first conveying part 36 to the first fixing plate 31, the insertion tube 311, and the fixing chuck ( 312) is easily inserted into the copper tube 82 by sequentially passing through it.

Then, the transfer control unit 39 moves the first transfer unit 36 in the horizontal direction so that the first expanding tube member 37 is inserted into the copper tube 82 .

A lead screw 35 for horizontally moving the first transfer unit 36 is mounted on one surface of the transfer control unit 39 .

The lead screw 35 rotates by a motor provided in the transfer control unit 39, and extends from the transfer control unit 39 toward the location where the copper tube fixing unit 30 is located. As a result, the first transfer unit 36 can be moved in the horizontal direction.

In the present invention, the first transfer part 36 is moved by applying a lead screw, but this is not limited to the present invention and various applications such as a cylinder are possible if it is to move the first transfer part 36 will be.

On the other hand, the guide member support portion 38 is further provided on the upper side of the frame of the first expansion means 3 having the configuration as described above.

The guide member support part 38 has a cylindrical shape elongated in the horizontal direction, and is provided through the upper surfaces of both ends of the first transfer part 36 and the transfer guide member 32, so that the first transfer part 36 ) and a plurality of transfer guide members 32 are supported and at the same time guide the movement direction.

The guide member support 38 is provided on both sides one by one so that the first transfer part 36 and the plurality of transfer guide members 32 perform high-precision movement and expansion of the tube without flow.

Accordingly, the first transfer unit 36 rotates the lead screw 35 by the transfer control unit 39 while the first transfer unit 36 performs the pipe expansion operation by the first tube expansion member 37 . is advanced, and accordingly, as the transfer guide member 32 advances together, the first expanded pipe member 37 penetrates the copper pipe fixing part 30 and is deeply inserted into the copper pipe 82 and the first expanded pipe The member 37 expands the inner diameter of the copper tube 82 .

And, after the inner diameter of the copper tube 82 is enlarged according to the operation as described above, the lead screw 35 is reversely rotated by the transfer control unit 39 and the first transfer unit 36 is moved backward, and accordingly As the transfer guide member 32 moves backward together, the first expanding pipe member 37 comes out of the inside of the copper pipe 82 , and the copper pipe fixing part 30 also moves backward from the end of the copper pipe 82 . are separated

Next, the second pipe expansion means (4) expands one end of the copper pipe (82) expanded by the first pipe expansion means (3).

The second pipe expansion means 4 is mounted so as to be lifted up and down on a second transfer part 40 to be described later, and is located between the heat exchanger fixing part 2 and the first pipe expansion means 3 .

The second expansion means 4 is a lower expansion member 406 and an upper expansion member 408 for performing the end expansion of the copper pipe 82, and the lower expansion member 406 and the upper expansion member 408 are fixed. It is configured to include a second fixing plate 402 and a second support plate 404 to be mounted.

In the second expansion means (4), one end of the copper pipe (82) whose inner diameter has been expanded by the first expansion member (37) is expanded with a lower expansion member (406) or an upper pipe member (408).

As shown in FIG. 10 , the lower expanding member 406 and the upper expanding member 408 include a fixed part 408a, a tool body 408b, expanded pipe parts 408c and 408c', and guide parts 408d and 408d'. ), including the insertion portion 408e.

8 is an enlarged view of any one of the upper expansion members 408 fixed to the second fixing plate 402, explaining the shape of the pipe expansion member performing the pipe expansion operation in the combined pipe expansion and freaming processing apparatus of the present invention It is shown for

To describe the shape of the expansion member based on the upper expansion member 408 , a fixing part 408a for being fixedly mounted to the second fixing plate 402 is formed on one side of the top expansion member 408 in a cylindrical shape.

The fixing portion 408a is a portion where the first expanding tube member 37 is mounted in the same manner as the fixing member 364 of the first inserting plate 360b described above.

In other words, although not shown in the drawings, a groove of the same shape as the key groove 374 recessed in one end of the first expanding pipe member 37 is recessed at one end of the fixing part 408a, and the second As the fixing member ( ) is provided in each of the plurality of holes formed in the fixing plate (360c), the fixing member ( ) and the groove formed in the fixing part (408a) are coupled to each other to achieve fixing.

In addition, a tool body 408b having a larger diameter than the fixing part 408a is formed in a cylindrical shape on the right side of the fixing part 408a (refer to FIG. 4 ) to support the upper expansion tube member 408 .

A second expanded pipe portion 408c' of an inclined shape is formed on the right side of the tool body 408b (based on FIG. 4) to have a smaller diameter than the right side of the tool body 408b.

In addition, a cylindrical second guide part 408d' is formed to be elongated on the right side (refer to FIG. 4) of the second expanded pipe part 408c'.

It is preferable that the second guide part 408d' has the same diameter as that of the right side of the second expanded pipe part 408c'.

On the right side of the second guide part 408d', a first expanded pipe part 408c inclined to have a smaller diameter than that of the right side of the second guide part 408d' is formed.

In addition, a first guide portion 408d is formed to have the same diameter as that of the right surface of the first expanded tube portion 408c and to extend to the right side of the first expanded tube portion 408c.

On the right side of the first guide part 408d, an insertion part 408e having a tapered shape, the diameter of which gradually decreases toward the right, is formed.

According to the expansion member having the above shape, the expansion member fixed to the second fixing plate 402 by the fixing part 408a is the first to the copper pipe 82 when the inner diameter of the copper pipe 82 is expanded. The insertion portion 408e is inserted inside, and then the first guide portion 408d, the first expanded tube portion 408c, the second guide portion 408d', and the second expanded tube portion 408c' are sequentially inserted. do.

As such, by sequentially inserting the expanding member into the copper pipe 82, the expansion of the copper pipe 82 can be performed. Depending on the angle, one end of the copper tube 82 may be expanded to a desired diameter and shape.

The upper expanded pipe member 408 applied to the present invention is inserted into one end of the copper pipe 82, and at the same time its diameter is expanded by the first expanded pipe part 408c, and by the second expanded pipe part 408c'. The end of the previously expanded shape is expanded in the shape of a trumpet.

This also applies to the lower expansion member 406 as well.

The lower expanded pipe member 406 and the upper expanded pipe member 408 having such a shape are fixed and mounted on the lower end and upper end of one surface of the second fixing plate 402 by the fixing member 364, respectively.

The second fixing plate 402 serves the same role as the first fixing plate 31 described above, and has a plate shape for fixing and mounting the lower expanded pipe member 406 and the upper expanded pipe member 408, A plurality of holes are formed so that the lower expansion member 406 and the upper expansion member 408 are replaced or mounted by a manual replacement operation of an operator.

A groove is recessed for a certain section at the lower end of the hole, and as a fixing member 364 applied to the first insertion plate 360b is provided inside the groove, the lower expansion member 406 and the upper expansion member 408 are provided. ) is inserted and fixed and mounted by a groove formed at one end thereof.

Accordingly, a plurality of lower expanded pipe members 406 are mounted on the lower end of the second fixing plate 402 and a plurality of upper expanded pipe members 408 are mounted on the upper end of the second fixing plate 402 .

And, when it is desired to expand the copper pipe 82 to be expanded, some copper pipes 82 are expanded by the lower expansion member 406, and the remaining copper pipes 82 are expanded by the upper expansion member 408, so that the copper pipe ( 82) to carry out the expansion work.

Accordingly, when the copper tube 82 of the stacked heat exchanger 8 is expanded, the second horizontal cylinder 44 moves the lower expanding member 406 and the upper expanding member 408 by dividing the pipe expansion work. has the advantage of being reduced.

Next, the second support plate 404 is formed in a plate shape, and is a member mounted on the rear surface of the second fixing plate 402 to support the second fixing plate 402 .

The second support plate 404 has both ends of the lower expansion member 406 and the upper pipe expansion member 408 in the transport direction so that the pipe expansion work can be easily performed by being engaged with the second conveying part 40 to be described later. It serves to guide and support the second fixing plate 402 at the same time.

Next, the second transfer unit 40 is a device for moving the lower expanded pipe member 406 and the upper expanded pipe member 408 in the horizontal and vertical directions.

The second conveying part 40 is provided between the heat exchanger fixing part 2 and the first expanding pipe 3 to guide the transport of the lower expanded pipe member 406 and the upper expanded pipe member 408 and at the same time, the It serves to support the second support plate 404 .

As shown in the drawing, the second transfer unit 40 includes a second guide member 41 , a first elevating cylinder 42 , a second horizontal cylinder 44 , and a second elevating cylinder 46 . is composed

The second guide member 41 is a member for fixing and supporting the second support plate 404 , and a pair is preferably provided to support both ends of the second support plate 404 .

A first elevating cylinder 42 is mounted on each of these second guide members 41 .

The first elevating cylinder 42 is a cylinder that moves the second support plate 404 in the vertical direction, and since it is the same as a general cylinder, a detailed description thereof will be omitted.

Meanwhile, a pair of lifting rails 410 for guiding the vertical movement direction of the second support plate 404 are provided on the inner surface of the second guide member 41, thereby operating the first lifting cylinder 42. When the second support plate 404 is easily moved in the vertical direction along the lifting rail (410).

In this way, the second support plate 404 is lowered by the first elevating cylinder 42, and the second support plate 404 is moved in the horizontal direction for proper tube expansion after descending to perform tube expansion.

Here, the second support plate 404 is moved in the horizontal direction by the second horizontal cylinder 44 .

The second horizontal cylinder 44 allows one end of the copper tube 82 to be expanded by the lower expanding member 406 or the upper expanding member 408 while moving the second supporting plate 404 in the horizontal direction.

On the other hand, each of the second guide members 41 is provided with a cylinder fixing member having a cross section of a '⊂' or '⊃' shape when viewed from the front, and the vertical surface of the cylinder fixing member ('|' among ⊂ or ⊃) surface) so that the second horizontal cylinder 44 is mounted to move the second support plate 404 in the horizontal direction.

The second horizontal cylinder 44 serves the same role as the first horizontal cylinder 314 , and since it is one of general types of cylinders, a detailed description thereof will be omitted.

A second elevating cylinder 46 for elevating the second fixing plate 402 is further provided on the upper surface of the second supporting plate 404 .

In the second pipe expansion means 4, as described above, some copper pipes 82 are expanded by the lower expansion member 406, and then the remaining copper pipes 82 are expanded by the upper expansion member 408. In this case, the second elevating cylinder 46 is a cylinder for moving the second fixing plate 402 in order to expand the remaining copper pipe 82 by the upper expansion member 408 .

The second lifting cylinder 46 is fixed to the upper surface of the second support plate 404 and is mounted in engagement with the second fixing plate 402 so that the second fixing plate 402 is vertically raised and lowered during the lifting operation. .

As such, when the second fixing plate 402 is lowered, the second supporting plate 404 is moved by the second horizontal cylinder 44 again, so that the upper expansion member 408 mounted on the upper end of the second fixing plate 402 is mounted. ) to perform the expansion of the remaining copper tube 82 by the

Referring again to the second transfer unit 40 having the configuration as described above, after the inner diameter of the copper tube 82 is expanded by the first expanding member 37 of the first expanding means 3, the second 1 The pipe expansion member 3 and the copper pipe fixing part 30 move backward, and after the second support plate 404 located on the upper side is lowered by the second transport part 40, the second horizontal cylinder 44 By advancing, a part of the copper tube 82 is expanded to the lower expansion member 406 and expanded into a trumpet shape through flaring processing. Then, when the second horizontal cylinder 44 moves backward, only the second fixing plate 402 is lowered by the second elevating cylinder 46 and the second horizontal cylinder 44 moves forward again, so that the upper expansion member ( 408), the remaining copper tube 82 is expanded into a trumpet shape through expansion and flaring processing.

Hereinafter, a method of expanding the tube using the combined apparatus for expanding and fretting of the present invention will be described with reference to the accompanying FIGS. 11 and 12 .

The pipe expansion and flaring processing composite device of the present invention stacks a plurality of heat exchangers 8 to expand the inner diameter and end of the copper pipe 82 installed through each heat exchanger 8, so that the following has different lengths A case in which two heat exchangers 8 (hereinafter referred to as “first heat exchanger” and “second heat exchanger”) are stacked and the pipe expansion operation is performed at the same time as an example will be described.

First, the first heat exchanger and the second heat exchanger to be expanded are stacked and placed on the upper surface of the heat exchanger transfer unit 1 .

At this time, the horizontal or vertical surfaces of the first heat exchanger and the second heat exchanger should be located at the same point.

That is, it is preferable that the first heat exchanger and the second heat exchanger are stacked so that one end of the copper tube 82 for which the pipe expansion operation is performed is located at the same point.

Then, after fixing one surface of the heat exchanger 8 with the plate, the operator starts the operation of the heat exchanger transfer unit 1 by the control device.

When the operation of the heat exchanger transfer unit 1 is started, the transfer member 12 positioned at a lower height than the support member 10 rises to a height higher than the support member 10 .

And, the transfer member 12 transfers the heat exchanger 8 by rotating in the direction in which the heat exchanger fixing part 2 is located.

At this time, the heat exchanger transfer member 28 of the heat exchanger fixing unit 2 is also positioned at a lower height than the heat exchanger support member 20 , and the transfer member 12 of the heat exchanger transfer unit 1 is supported. At the same time as being raised to a higher height than the member 10 , the heat exchanger transfer member 28 also rises to the same height as the height at which the transfer member 12 of the heat exchanger transfer unit 1 is raised.

In addition, the heat exchanger transfer unit 1 transfers the heat exchanger 8 while rotating in the same direction as the rotation direction of the transfer member 12 .

Accordingly, the heat exchanger 8 is easily transferred to the heat exchanger fixing part 2 .

Here, a member blocking the advancement of the heat exchanger 8 is protruded from the end of the plurality of heat exchanger support members 20 so that when the heat exchanger 8 is advanced, the heat exchanger 8 is protruded by the protruding member. Let the progress stop.

As described above, when the advance of the heat exchanger 8 is stopped, the transfer member 12 of the heat exchanger transfer unit 1 and the heat exchanger transfer member 28 of the heat exchanger fixing unit 2 stop rotating, and at the same time It returns to the height at which it was placed.

In other words, it is positioned by descending to a height lower than the height of the heat exchanger support member 20 or the support member 10 .

Then, the plurality of heat exchanger fixing plates 22 are simultaneously lowered to the upper surface of the heat exchanger 8 located on the upper surface of the heat exchanger support member 20 so that the heat exchanger 8 does not deviate from the designated position. .

At this time, it is possible for each of the heat exchanger fixing plates 22 to come down according to the cylinder operation of the fixing plate support 24 .

Then, the holding member 260 of the fixing guide part 26 fixes one end of the copper tube 82 .

At this time, as the pressure cylinder 264 of the fixing guide part 26 operates, the holding member fixing plate 262 advances to one side of the laminated heat exchanger 8, so that the holding member 260 causes the heat exchanger ( 8) can be fixed.

Here, since the holding member 260 has the same shape as the one end of the copper tube 82 on which the expansion operation is not performed, it is possible to perform more rigid fixing, and the length of the copper tube 82 to be expanded is contracted. it can be prevented

Then, the first horizontal cylinder 314 is operated to move the copper tube fixing part 30 of the first expanding means 3 in the horizontal direction.

At this time, the copper tube fixing member 310 mounted on the copper tube fixing part 30 holds and fixes one end of the copper tube 82 .

Next, as shown in FIG. 11 , the first conveying part 36 is operated to move the first expanding pipe member 37 in the horizontal direction.

At this time, while the first conveying part 36 of the first pipe expansion means 3 is advanced in the horizontal direction by the conveying control part 39 , the first expanding pipe member 37 is moved to the rear of the copper pipe fixing part 310 . transport

The first expansion member 37 is inserted through the rear of the copper pipe fixing part 30 according to the movement of the first conveying part 36 and then the copper pipe fixing member 310 mounted on the copper pipe fixing part 30 is removed. It penetrates and is deeply inserted into the copper tube 82 to enlarge the inner diameter of the copper tube 82 .

Here, the fixing chuck 312 of the copper tube fixing member 310 holds and fixes one end of the copper tube 82 , and the first expansion member 37 is the first fixing plate ( 31), the insertion tube 311 of the copper tube fixing member 310, and the fixing chuck 312 are sequentially penetrated and then inserted into the copper tube 82 to perform the expansion operation, thereby reducing the length of the copper tube 82. At the same time, both the copper tube 82 of the first heat exchanger and the copper tube 82 of the second heat exchanger can be simultaneously expanded.

Next, after the inner diameter of the copper tube 82 is expanded, the first conveying part 36 is moved backward by the conveying control unit 39 and the first expanding member 37 inserted deep inside the copper tube 82 . is separated from the copper tube (82).

In addition, the copper tube fixing part 30 is also moved backward by the first horizontal cylinder 314 .

Then, the second support plate 404 descends along the lifting rail 410 by the first lifting cylinder 42 as shown in FIG. 12 .

At this time, the second support plate 404 is lowered to a height suitable for expanding one end of the copper tube 82 .

Then, the second support plate 404 is advanced by the second horizontal cylinder 44 .

At this time, the diameter of one end of a part of the copper tube 82 is expanded by the lower expansion member 406 fixed to the second fixing plate 402 and at the same time it is expanded in a trumpet shape.

After some copper tube 82 is expanded, the second support plate 404 is moved backward by the second horizontal cylinder 44 .

Then, the second support plate 404 maintains a lowered state, and in this state, the second fixing plate 402 is lowered by the second elevating cylinder 46 .

And, as the second support plate 404 is advanced by the second horizontal cylinder 44, the diameter of one end of the remaining copper tube 82 is expanded by the upper expansion member 408 of the second fixing plate 402. At the same time, it is expanded in the shape of a trumpet.

After performing the expansion of the remaining copper tube 82 as described above, the second support plate 404 is moved backward by the second horizontal cylinder 44, and the first lifting cylinder 42 and the second lifting cylinder 46 are performed. ), the second expansion means (4) is returned to its original position by operating at the same time.

Then, the heat exchanger fixing plate 22 of the heat exchanger fixing part 2 rises upward by the cylinder operation of the fixing plate support 24, and the holding member 260 holding one end of the copper tube 82 is It moves backward by the pressure cylinder 264 .

Accordingly, the heat exchanger (8) freed from all fixing and pressurization is carried out by the heat exchanger transfer member (28) of the heat exchanger fixing part (2) and the transfer member (12) of the heat exchanger transfer part (1). It is transferred to the group transfer unit (1).

Likewise at this time, for the transfer of the heat exchanger 8, the heat exchanger transfer member 28 of the heat exchanger fixing unit 2 and the transfer member 12 of the heat exchanger transfer unit 1 are connected to the heat exchanger support member ( 20) and the support member 10, the heat exchanger transfer member 28 rotates in the direction in which the heat exchanger transfer unit 1 is positioned to transfer the heat exchanger 8.

Here, the transfer member 12 of the heat exchanger transfer unit 1 also rotates in the same direction as the heat exchanger transfer member 28 , so that the heat exchanger 8 can be more easily transferred.

Accordingly, the pipe expansion operation of the copper pipe 82 is completed by transferring the heat exchanger 8 on which the pipe expansion operation has been performed by the pipe expansion device of the present invention from the heat exchanger fixing unit 2 to the heat exchanger conveying unit 1 .

The scope of the present invention is not limited to the embodiments illustrated above, and within the technical scope as described above, many other modifications based on the present invention will be possible for those skilled in the art.

1. Heat exchanger transfer part 2. Heat exchanger fixing part
3. 1st pipe expansion means 4. 2nd transfer unit
8. Heat exchanger 10. Support member
12. Transfer member 20. Heat exchanger support member
22.Heat exchanger fixing plate 24.Fixing plate support
26.Fixed guide part 28.Heat exchanger transfer member
30. Copper tube fixed part 31. 1st fixed plate
32. Transfer guide member 33. Distance maintaining block
34. Transport guide rail 35. Lead screw
36. 1st transfer part 37. 1st pipe expansion member
38. Guide member support part 39. Transfer control part
40. Second transfer unit 41. Second guide member
42. 1st elevating cylinder 44. 2nd horizontal cylinder
46. 2nd elevating cylinder 80. Pin plate
82. Copper tube 260. Holding member
262. Holding member fixing plate 264. Pressurizing cylinder
266. Fixed plate transfer means 310. Copper tube fixing member
311. Insertion tube 312. Fixed chuck
314. First horizontal cylinder 350. First upper lift plate
352. First lower lifting plate 354. Second lower lifting plate
356.Second upper lifting plate 360.Fixing part of expanding pipe member
360a. Base plate 361. Upper cylinder
361'. Lower cylinder 362. Insertion hole
363.Fixed groove 364.Fixed member
365. Elastic member 366. Fixing projection
367. Jamming 370. Straight part
372. First expansion tool 374. Keyway
402. Second fixed plate 404. Second support plate
406. Lower pipe member 408. Upper pipe member
410. Lifting rail

Claims (5)

a heat exchanger fixing unit for fixing and supporting the heat exchanger;
A first conveying part provided with a first expanding member for expanding the inner diameter of the copper pipe, an expanding member fixing part for fixing the first expanding member, and moving the first expanding member in a horizontal direction, and a copper pipe holding one end of the copper pipe a first pipe expansion means provided with a copper pipe fixing part to which a plurality of fixing members are mounted;
A lower expansion member and an upper expansion member for expanding one end of the copper tube, a second fixing plate on which the lower expansion member and the upper expansion member are mounted, a second support plate mounted on one surface of the second fixing plate, and the second fixing plate or has a configuration including a second expansion means provided with a second transfer unit for moving the second support plate in the vertical and horizontal directions;
The expansion member fixing part,
A plurality of insertion plates through which a plurality of insertion holes into which the first expansion member is inserted are formed, a plurality of lifting plates provided to enable lifting and lowering between some of the inserting plates, and the lifting plates are respectively connected to the lifting plates so that the lifting plates are raised and lowered Combination apparatus for pipe expansion and flaring processing, characterized in that it has a configuration that includes a cylinder. According to claim 1, wherein the insert plate,
Consists of a first insert plate, a second insert plate, a third insert plate, and a fourth insert plate,
A fixing groove provided with a fixing member for fixing the first expanding pipe member to be inserted into the insertion hole is formed in a depression below the insertion hole formed in the first insertion plate,
A fixing protrusion protruding upward is formed on the upper surface of the fixing member, and an elastic member for pressing the fixing member upward is provided inside the fixing member. According to claim 2, wherein the first expansion member,
A key groove is recessed at one end,
When inserted into the insertion hole of the first insertion plate, the first expansion member is fixed to the first insertion plate while the fixing protrusion and the key groove of the fixing member are coupled to each other. According to claim 1, wherein the second transfer unit,
a second guide member for fixing and supporting the second support plate and guiding a transfer direction of the second support plate;
a first lifting cylinder mounted on the second guide member and configured to vertically elevate the second support plate;
a second horizontal cylinder for moving the second support plate in a horizontal direction;
It is mounted on the second support plate, and characterized in that it has a configuration including a second lifting cylinder that allows the second fixing plate to be lifted up and down in the vertical direction. According to claim 1, wherein the heat exchanger fixing part
A fixing guide part for holding and fixing one end of the copper tube is included and provided,
The fixed guide part,
a holding member for fixing the copper tube by holding one end of the copper tube;
a holding member fixing plate to which the holding member is fixedly mounted;
A pressure cylinder installed on one side of the holding member fixing plate and moving the holding member in the horizontal direction; Combination pipe expansion and flare processing apparatus comprising a.

Images